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Superconduction and qubits

Superconduction and qubits


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Qubits are here in this model



The qubits and the model of sliding window (Image I)

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1) The oscillation of atoms would make the qubit possible.


As you might know, this is the writing about quantum computers. The question is is it possible to make the quantum computer, what is the size of a laptop, and operate at room temperature. The answer is that the photon-qubits would make this kind of system possible. The idea is that the data is stored in the small mass memories in the line form. 


2) The sliding window as the model of the system. What turns the row of data to the linear model. 


The idea is similar to the "sliding window" of the TCP/IP-protocol. But in this case, the sliding window would read the data to qubits. And this protocol has been given ideas, that one computer would be acting as the "sliding window". The data would read to hard disks, and then the data would send to the series of computers at the same time, which will process at the same time. 


This might be extremely large size quantum computer simulation. The image I portrait the "sliding window". In the use of the quantum computer, the frame would slide over the bit row, and then sends those bits to the qubits. Which are in the line above the sliding window. 


That means that the "sliding window" would load the data from the regular computer, and store it to those small mass memories. Then the data would send in the precise same time with the lasers, which are connected to the memory blocks. And every each memory block has one laser. The thing is that the system operates with the regular, small-size computers what are the first store the data, and then send it forward. This kind of emulation system would be a clumsy model of the real quantum computer. 


(1) https://en.wikipedia.org/wiki/Sliding_window_protocol


Image: I https://www.researchgate.net/figure/TCP-sliding-window-mechanism_fig1_331853081


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Bose-Einstein condensate (Image II)


3) Bose-Einstein condensate and oscillation of superconducting atoms


Above this text is the image, which portraits the Bose-Einstein condensate(2) or simply the enlarged atom. The image is taken by using the scanning tunneling microscope, and it shows that one atom is bigger than others. The name Bose-Einstein condensate is causing, that the atoms, what are forming the Bose-Einstein condensate can act as the tiny capacitors. 


And the idea of the quantum mass memories is that in the extremely low temperature the electricity would be stored in the same form, where it is recorded. So the idea of the quantum mass-memory is that the single-atom can store the data if the temperature of the atom is low enough, which means the superconduction temperature. 


So in Bose-Einstein condensate, the electron layer of the atom is enlarging, which makes this fifth element of material very interesting tool for quantum computers. The temperature that allows forming the Bose-Einstein condensate is extremely low. That means that the atom is in the superconducting condition. At a temperature what is near absolute zero points, every material turns to superconducting. The superconducting mass memories can store extremely large data masses, but the single atom can form the qubit. 


4) The single-atom can form the qubit. In this case, a qubit is stored in the fullerene ball, where it can interact with those atoms. 


The thing is that the size of the qubit is not important. The qubit can be a molecule, atom size, or subatomic bite, where the data is loaded, and then that thing would transmit that data forward. So the single superconducting atom can work as the qubit. The idea is that the qubit is storing the data, and then transfer it to the electric wires, where those bits are traveling in line. 


That means that the qubit could be an atom that is stored in the small chamber. First, the data would be driven to that atom, and then the size of it would be changed. Then the atom what touches the chamber would release the bits, what are stored in that structure to the wire. The thing is that the qubit is the hard disk, what would store the data, what comes from the row, and transforms the row of bits to the line of bits. 


So the idea is that the size of an atom can be changed simply giving the laser bursts to that atom. And when the temperature of the atom is increasing, that thing makes the size of the atom decreases. 


The thing is that the atom would be stored the data when it is in small size, and when the temperature would decrease the size of an atom would be an increase. And those electromagnetic oscillations would pump to the chamber, where the oscillation that involves the bits would be transported to the microchannel. 


The problem is how to make those bits travel in a line? When we are thinking about the form of the qubit, the electric or electromagnetic qubit can turn to photon qubits simple by conducting the electric signals to lasers, which are sending the flashes of light or photons to the photovoltaic cell, what is forming the photons back to electric vortex. The ability to use photon-based qubits makes it possible to use very small cold chambers, which is protecting the unit that transforms the data row to the linear data. 


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5) The quantum computer would have two layers


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1) The regular computer, which will be used to input the data to the quantum computer, and where the processed data is read


2) The quantum layer where the data travels as the qubit. 

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And how to transform the linear data back to the row form of data? The answer is that the data packs what is traveling in the quantum computer would equip with the serial number. That number tells the computer the order of how to sort the data to the regular computer system. 


The regular computer sends the processed data to the screen. The light base qubit would make it possible to create the quantum computer, which can operate at room temperature. The transformation unit would be the size of the sugar bite, and that thing makes it possible to make the quite small-size but the same way effective supercomputer. 


(2) https://en.wikipedia.org/wiki/Bose%E2%80%93Einstein_condensate



Image II: https://phys.org/news/2009-09-german-scientists-bose-einstein-condensate-calcium.html

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